Data Analyzing Device

ABSTRACT

To make it easier to perform an in-depth analysis by presenting to a user which feature value influences and how it influences an objective variable in a case of automatically generating feature values. For each of a plurality of feature values, by determining a division point indicating a change in influence on an objective variable, each feature value is divided into a plurality of segments and an evaluation value is calculated using an influence degree of each segment on the objective variable as an index. The segments of the feature values for which the evaluation values have been calculated are displayed on a monitor.

CROSS-REFERENCE TO RELATED APPLICATIONS

The present application claims foreign priority based on Japanese Patent Application No. 2019-023918, filed Feb. 13, 2019, the contents of which is incorporated herein by reference.

BACKGROUND OF THE INVENTION 1. Field of the Invention

The present invention relates to a data analyzing device.

2. Description of Related Art

A technique for trying to acquire a useful unknown knowledge from a large volume of information, generally called “data mining”, is conventionally known. A typical method of data mining involves a pre-processing step, a feature extracting step, a model learning step, and a post-processing step that are sequentially executed. In the pre-processing step, operations such as collecting data necessary for analysis, and removing unnecessary noise from the data and filling a missing item to improve the efficiency of the analysis are performed. These operations are collectively referred as “ETL (extract, transform, and load)”. In the feature extracting step, a feature that exists in the original data is manipulated to generate a new feature more useful for the analysis. In the model learning step, data that is prepared in the pre-processing step and the feature extracting step is input to a machine learning algorithm to obtain an analysis result. In the post-processing step, the analysis result obtained in the model learning step is subjected to a process such as outputting it to an external device or generating a report based thereon.

To design an optimal feature, trial and error by an experienced analyst is necessary, resulting in taking a long time to analyze data. In response to this situation, a technique is disclosed in, for example, “A Randomized Exhaustive Propositionalization Approach for Molecule Classification” (INFORMS Journal on Computing, Vol. 23, No. 3 Published Aug. 31, 2010). This known technique performs automatic generation of a new feature from data.

The technique disclosed in such a literature involves comprehensively applying a preliminarily defined series of arithmetic operators, such as a plus (+) operator, a minus (−) operator, a multiplication (×) operator, and a division (+) operator, to an original feature, thereby automatically generating a large amount of new features.

In “A Randomized Exhaustive Propositionalization Approach for Molecule Classification” (May 26, 2010), a new feature value can be automatically generated. However, when seen from a user of the system, it is unclear which feature value influences and how the feature value influences an objective variable, and it is not easy to conduct an in-depth analysis.

SUMMARY OF THE INVENTION

The invention has been made in view of the above problems, and an object of the invention is to make it easier to perform an in-depth analysis by presenting to a user which feature value influences and how it influences an objective variable in a case of automatically generating feature values.

In order to achieve the object, in a first invention, a data analyzing device for analyzing analysis target data includes a data input unit which receives an input of analysis target data including a plurality of attributes, a feature value automatic generating unit which automatically generates a new feature value by applying a predetermined function to a single attribute or a combination of a plurality of attributes, an analyzing unit which generates a prediction model for predicting an objective variable based on feature values of a plurality of attributes including a feature value of an original attribute included in the analysis target data and a new feature value generated by the feature value automatic generating unit, an evaluating unit which, for each of the plurality of feature values, by determining a division point indicating a change in influence on an objective variable, divides each feature value into a plurality of segments and calculates an evaluation value using an influence degree of each segment on the objective variable as an index, and a display unit which displays the segments of the feature values for which the evaluation values have been calculated by the evaluating unit.

According to this configuration, when analysis target data including a plurality of attributes is input, a new feature value is automatically generated by applying a predetermined function to a single attribute or a combination of a plurality of attributes. Then, a prediction model for predicting an objective variable is generated based on a plurality of feature values including a feature value of an original attribute included in the analysis target data and a new feature value. For each of the plurality of feature values, when a division point indicating a change in influence on an objective variable is determined and each feature value is divided into a plurality of segments, an evaluation value is calculated using an influence degree of each segment on the objective variable as an index. Since the segments of the feature values for which the evaluation values have been calculated are displayed, a user can grasp which feature value influences and how it influences the objective variable.

In a second invention, the display unit is configured to selectively display the segments of the feature values for which the evaluation values have been calculated by the evaluating unit.

According to this configuration, it is possible to selectively display on the display unit a part of the segments of the feature values for which the evaluation values have been calculated. Therefore, for example, it is possible to present only important information to a user by not displaying segments having a low evaluation value.

In a third invention, the display unit is configured to preferentially display the segments of the feature values for which the evaluation values have been calculated by the evaluating unit.

According to this configuration, since the segments of the feature values for which the evaluation values have been calculated are preferentially displayed on the display unit, it is possible to easily grasp a segment having a high influence degree on the objective variable.

In a fourth invention, the display unit is configured to display a segment of a feature value having a high-ranking evaluation value calculated by the evaluating unit.

According to this configuration, a segment of a feature value having a high-ranking evaluation value is a segment having a high influence degree on the objective variable and this segment is displayed on the display unit. Therefore, it is possible to easily grasp a segment having a high influence degree.

In a fifth invention, the evaluating unit is configured to determine the division point where the evaluation value is optimal.

According to this configuration, it is possible to grasp a segment that is important for data analysis.

In a sixth invention, the evaluating unit is configured to, by determining a division point indicating a change in influence on an objective variable under a compound condition combining a plurality of feature values, divide each feature value into a plurality of segments and calculate an evaluation value using an influence degree of each segment on the objective variable as an index, and the display unit is configured to display the segments of the feature values for which the evaluation values under the compound condition have been calculated.

According to this configuration, in a case of a compound condition combining a plurality of feature values, it is possible to grasp a segment having a high influence degree on the objective variable.

In a seventh invention, the evaluating unit is configured to calculate a share of data included in the segments, and the display unit is configured to display the share calculated by the evaluating unit.

According to this configuration, it is possible to conduct an in-depth analysis by grasping the share of data included in the segments.

In an eighth invention, the evaluating unit is configured to calculate an average value of objective variables, and the display unit is configured to display the average value of the objective variables.

According to this configuration, it is possible to compare the average value of the objective variables and the segments.

In a ninth invention, the display unit is configured to be capable of displaying switching between a first display form in which a segment having one feature value is displayed and a second display form in which a segment having a plurality of feature values is displayed.

According to this configuration, for example, when a segment having one feature value is displayed, it may be displayed in a display form such as a line graph, and when a segment having two feature values is displayed, it may be displayed in a display form such as a cross-tabulation table. In this way, it is possible to select an appropriate display form corresponding to the number of feature values.

In a tenth invention, the display unit is configured to display a relation between a representative value of a plurality of feature values used in the prediction model and a numeric value of an objective variable, and the data analyzing device further includes an adjusting unit which receives an adjustment of the representative value based on a user's operation input, and a simulation unit which changes the feature values of a plurality of attributes according to adjustment amount of the representative value, recalculates the numeric value of the objective variable from the prediction model and displays on the display unit.

According to this configuration, since a relation between a representative value of a plurality of feature values used in the prediction model and a numeric value of an objective variable is displayed on the display unit, it is possible for a user to grasp the relation between the representative value of the plurality of feature values and the numeric value of the objective variable. When the user adjusts the representative value, the adjustment is received by the adjusting unit, the simulation unit changes the feature values of a plurality of attributes according to adjustment amount of the representative value and recalculates the numeric value of the objective variable from the prediction model, and the calculation result is displayed on the display unit. In this way, it is possible to simulate the change of the objective variable due to the change of the value of the feature values. Therefore, it is possible to determine in advance the propriety of a measure by simulating the change of the objective variable due to the change of the value of the feature values.

According to the invention, it is possible to generate a prediction model based on a new feature value automatically generated by the feature value automatic generating unit and a feature value of an original attribute included in the analysis target data, and it is possible to divide, for each of a plurality of feature values, by determining a division point indicating a change in influence on an objective variable, each feature value into a plurality of segments and calculate an evaluation value using an influence degree of each segment on the objective variable as an index. Then, since the segments of the feature values for which the evaluation values have been calculated are displayed on the display unit, it is possible to present to the user which feature value influences and how it influences the objective variable and on this basis, the user can easily conduct an in-depth analysis.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a diagram showing a schematic configuration of a data analyzing device according to an embodiment of the invention;

FIG. 2 is a block diagram of a data analyzing device;

FIG. 3 is a flowchart showing a procedure of data analysis;

FIG. 4 is a diagram showing a user interface for data input;

FIG. 5 is a flowchart showing operations of the data analyzing device;

FIG. 6 is a diagram showing a user interface for relation definition;

FIG. 7 is a diagram showing an example of a relation between tables;

FIG. 8 is a diagram explaining three types of multiplicity;

FIG. 9 is a diagram explaining a case where original attribute values are used as objective variable candidates;

FIG. 10 is a diagram explaining a case where original attribute values are converted into flags;

FIG. 11 is a diagram explaining a case where original attribute values are aggregated per group of other attribute values;

FIG. 12 is a diagram showing objective variable candidates generated by aggregating original attribute values per group of other attribute values;

FIG. 13 is a diagram explaining a case where tables are aggregated per group of other tables;

FIG. 14 is a diagram showing objective variable candidates generated by aggregating tables per group of other tables;

FIG. 15 is a diagram showing objective variable candidates automatically generated by an objective variable candidate generating unit;

FIG. 16 is a user interface for keyword input, where FIG. 16A shows a case where one keyword is input and FIG. 16B shows a case where two keywords are input.

FIG. 17 is a diagram showing a user interface for editing;

FIG. 18 is a diagram showing a user interface of preview display;

FIG. 19 is a diagram showing an example in which feature values are generated using only data prior to a period used for totaling objective variables;

FIG. 20 is a diagram showing a user interface for result display;

FIG. 21A is a diagram showing a user interface for refining showing a state of receiving a selection of attributes;

FIG. 21B is a diagram showing a user interface for refining showing a state in which selected objective variables are displayed in order of scores;

FIG. 21C is a diagram showing a user interface for refining showing a state in which an alias is specified for an objective variable;

FIG. 22 is a diagram showing a method of holding internal data according to a first example;

FIG. 23 is a diagram showing a method of holding internal data according to a second example;

FIG. 24 is a diagram showing a method of holding internal data according to a third example;

FIG. 25 is a flowchart showing a processing procedure executed by an automatic segmentation function;

FIG. 26 shows an example of an expression used when searching for a division point, and shows a case where an objective variable is binary and a case where an objective variable is a continuous value;

FIG. 27 is a diagram showing a relation between a division point where an evaluation value is optimal and a feature value;

FIG. 28 is a diagram showing a case where an evaluation value and an average value of objective variables are recalculated under simplified conditions;

FIG. 29 is a diagram showing the user interface for result display displaying a segment list;

FIG. 30 is a diagram showing a combination of an original feature value and a recommended feature value;

FIG. 31 is a diagram showing a user interface for detail display in a case where a segment having one feature value is displayed;

FIG. 32 is a diagram showing a user interface for detail display in a case where a segment having two feature values is displayed;

FIG. 33 is a diagram showing a user interface for output;

FIG. 34 is a diagram showing a user interface for simulation; and

FIG. 35 is a diagram explaining a calculation method when adjusting a representative value.

DESCRIPTION OF EMBODIMENTS

Embodiments of the invention are explained in detail below with reference to the drawings. However, the following description of the preferred embodiments is merely illustrative in nature, and is not intended to limit the invention, its applications, or its use.

FIG. 1 is a diagram showing a schematic configuration of a data analyzing device 1 according to an embodiment of the invention, and FIG. 2 is a block diagram of the data analyzing device 1. The data analyzing device 1 is a device that analyzes analysis target data, and by using the data analyzing device 1, a data analyzing method can be executed. The data analyzing device 1 and the data analyzing method can be used, for example, in performing the so-called data mining, which attempts to obtain useful knowledge that has been unknown from among a large amount of information.

Data Analysis Procedure

A general procedure of data analysis will be described based on the flowchart shown in FIG. 3. After the start, a pre-processing step is executed in step SA1. In the pre-processing step, data necessary for analysis, that is, analysis target data, is collected, and work such as removing unnecessary noise from the data and filling in missing items is performed in order to enhance the effect of the analysis. This work is called ETL: Extract/Transform/Load. In step SA2, a feature extraction step is executed. In the feature extraction step, feature values existing in the original data are processed to generate new feature values that are more useful for the analysis. In step SA3, a model learning step is executed. In the model learning step, the data prepared in the pre-processing step and the feature extraction step is input to a machine learning algorithm to obtain an analysis result. In step SA4, a post-processing step is executed. In the post-processing step, processing such as outputting the analysis result obtained in the model learning step to an external device and creating a report based on the analysis result is performed.

Overall Configuration of Data Analyzing Device 1

As shown in FIG. 1 and FIG. 2, the data analyzing device 1 includes a device main body 2, a monitor 3, a keyboard 4, and a mouse 5, and the monitor 3, the keyboard 4, and the mouse 5 are connected to the device main body 2. For example, the data analyzing device 1 can be obtained by installing a program capable of executing control content and processing content which will be described later in a general-purpose personal computer, and the data analyzing device 1 may also be configured by special-purpose hardware in which the program is installed. The device main body 2 and the monitor 3 may be integrated, or a part of the device main body 2 or a part of the functions executed by the device main body 2 may be incorporated into the monitor 3.

The data analyzing device 1 incorporates a communication module (not shown) and is configured to be capable of communicating with the outside. This enables, for example, downloading of data from an external server via Internet connection, etc.

The keyboard 4 and the mouse 5 are not only operating units operating the data analyzing device 1 but also input units inputting various kinds of information, selecting units performing selecting operations, etc. In addition to the keyboard 4 and the mouse 5, or in place of the keyboard 4 and the mouse 5, a touch panel type input device, a voice input device, a pen type input device and the like may be used.

Configuration of Monitor 3

The monitor 3 shown in FIG. 1 includes, for example, an organic EL display or a liquid crystal display, etc., and may be called a display unit alone, or the monitor 3 may be combined with a display control unit 3 a shown in FIG. 2 to be called a display unit. The display control unit 3 a may be incorporated in the monitor 3 or may be incorporated in the device main body 10. The display control unit 3 a includes a display DSP and the like which displays an image on the monitor 3. The display control unit 3 a may also include a video memory such as a VRAM which temporarily stores image data when displaying an image. The display control unit 3 a transmits a control signal for displaying a predetermined image on the monitor 3 based on a display instruction (display command) sent from a CPU 11 a of a main control unit 11 which will be described later. For example, in addition to various user interfaces that will be described later, control signals for displaying the operation contents of the user using an icon, the keyboard 4, and the mouse 5 on the monitor 3 are also transmitted. In addition, a pointer and the like operable by the mouse 5 can be displayed on the monitor 3.

By making the monitor 3 a touch operation panel type monitor, the monitor 3 can have a function of inputting various kinds of information, a function of operating the data analyzing device 1, and a selection operation function.

Overall Configuration of Device Main Body 2

The device main body 2 shown in FIG. 1 includes a control unit 10 and a storing unit 30. The storing unit 30 includes a hard disk drive, a solid state drive (SSD), and the like. The storing unit 30 is connected to the control unit 10 and is controlled by the control unit 10. The storing unit 30 can save various kinds of data, and can also read the saved data.

Control Unit 10

Though not specifically shown, the control unit 10 may include an MPU, a system LSI, a DSP, a special-purpose hardware, etc. The control unit 10 bears various functions as will be described later. However, these functions may be realized by a logic circuit, or may be realized by executing software.

As shown in FIG. 2, the control unit 10 includes the main control unit 11, a data input unit 12, a type recognizing unit 13, an objective variable candidate generating unit 14, a feature value automatic generating unit 15, a score calculating unit 16, a keyword input unit 18, an attribute selecting unit 19, a selection receiving unit 20, and an analyzing unit 21. Each unit of the control unit 10 is described separately for each part above. However, it may be configured that a same part executes a plurality of types of processing, or it may be configured that it is further divided and a plurality of parts executes one process in cooperation. Each of the aforementioned hardware is connected via an electrical communication path (wiring) such as a bus B so as to enable bidirectional communication or unidirectional communication as required.

The main control unit 11 performs numerical calculation, arithmetic processing, and various kinds of information processing based on various programs, and also controls each part of the hardware. The main control unit 11 includes the CPU 11 a that functions as a central processing unit, a work memory 11 b such as RAM that functions as a work area when the main control unit 11 executes various programs, and a program memory 11 c such as ROM, flash ROM and EEPROM in which a startup program, an initialization program, etc. are stored.

The data input unit 12 is a part that receives an input of analysis target data including a plurality of attributes, and by the data input unit 12, it is possible to execute step SB1 in the flowchart shown in FIG. 5. Here, it is assumed that the analysis target data to be input is data (table) of one or more table forms. The data input unit 12 generates a user interface for data input 50 shown in FIG. 4 to display on the monitor 3, and also receives a user's operation performed on the user interface for data input 50. The user's operation includes, for example, operation of the keyboard 4, operation of the mouse 5 (including button click, drag and drop, rotation of a wheel, etc.), tap operation to a touch panel type input device, drag operation, etc., and may be any of these operations. The same applies below.

Here, the analysis target data is data including a plurality of attributes. An attribute is an item including a pair of name and type included in the analysis target data, and for example, a user ID, age, gender and the like generally exist. An attribute type is a classification that defines what value an attribute can be, and the method of classification differs in systems. For example, in a general relational database, any one of data types such as INT type (integer), REAL type (real number), DATE type (date), and VARCHAR type (character string) is assigned per attribute. Examples of the INT type include age and purchase price, examples of the REAL type include interest rates, examples of the DATE type include the date of birth, and examples of the VARCHAR type include user names, email addresses, etc.

In data analyzing, after the analysis target data is taken from a relational database on the data analyzing device (or a program) that performs data analysis, an attribute type on the data analyzing device 1 is defined in step SBla in the flowchart shown in FIG. 5. In this example, three kinds of types, i.e., a numeric type of attribute including integer and real number, a date type of attribute including time information such as year-month-date, and a category type of attribute which is neither a numeric type nor a date type, are defined as types on the data analyzing device 1. When defining the type of attribute on the data analyzing device 1, the data analyzing device 1 may automatically define from the types of the relational database based on a predetermined rule, or a user of the data analyzing device 1 may define. In addition, it may be set that after the data analyzing device 1 automatically defines, the user of the data analyzing device 1 may confirm and make corrections when necessary.

That is, the attribute type included in the analysis target data includes a numeric type indicating that it is a numeric value, a date type indicating that it is a date, and a category type indicating that it is a category other than the numeric value and the date. The type recognizing unit 13 shown in FIG. 2 is configured to recognize whether a type of an attribute value of each attribute of the analysis target data input to the data input unit 12 is a numeric type indicating that it is a numeric value or a category type indicating that it is a category by determining the types of the attributes included in the analysis target data. The type recognizing unit 13 is a part that executes a type recognizing step of step SB1 b in the flowchart shown in FIG. 5. The type recognizing unit 13 can also recognize whether the type of an attribute value of each attribute of the analysis target data is a date type. The result recognized by the type recognizing unit 13 is output to the objective variable candidate generating unit 14. The result recognized by the type recognizing unit 13 may also be stored in the storing unit 30. In this case, the objective variable candidate generating unit 14 reads the recognition result of the type recognizing unit 13 from the storing unit 30.

In addition, it is fine that part of the analysis target data is missing. In this case, as shown in step SB1 c in the flowchart shown in FIG. 5, it is only necessary to perform an operation (ETL processing) of filling in the missing items. Details of the ETL processing will be described later.

The user interface for data input 50 shown in FIG. 4 is provided with a file selecting button 50 a, a database selecting button 50 b, a URL specifying button 50 c, a database display region 50 d, and a reading start button 50 e. The arrangement of each button can be set freely.

For example, when a file storing the analysis target data is saved in an external storing device or the storing unit 30 and is on the desktop or in an open folder, the user performs an operation of dragging and dropping the file to the database display region 50 d. As a result, the name of the file storing the analysis target data is displayed in the database display region 50 d. Then, when the reading start button 50 e is pressed, the file displayed in the database display region 50 d is read and saved in a predetermined region of the storing unit 30.

When the analysis target data is on a database, the user presses the database selecting button 50 b. When the database selecting button 50 b is pressed, a setting screen (not shown) for connecting to the database is displayed, prompting the user to input a table name and, when necessary, a password. Then, when the reading start button 50 e is pressed, the analysis target data is read and saved in a predetermined region of the storing unit 30 in a predetermined file format, and the file name storing the analysis target data is displayed in the database display region 50 d.

When the analysis target data is on the Internet or a server, the user presses the URL specifying button 50 c. When the URL specifying button 50 c is pressed, a URL input screen (not shown) is displayed, prompting the user to input a URL. Then, when the reading start button 50 e is pressed, the analysis target data is downloaded and is read and saved in a predetermined region of the storing unit 30 in a predetermined file format, and the file name storing the analysis target data is displayed in the database display region 50 d.

The file storing the analysis target data may be only one or plural. FIG. 4 shows a case where analysis data stored in two files of “transaction” and “master” is read. Files may be read by a method other than the three methods described above. Although the file format is csv format, it may be other formats, for example, a table on a relational database.

After the analysis target data is read, the type (for example, a numeric type, a category type, a date type) for analysis is set for each attribute. The type information may be analogized from the type on the relational database, for example, “being analogized as a numeric type in the case of INT type” on the database, or a specification of the type from the user may be received.

After the analysis target data is read, removal of missing values of the analysis target data and filling in the analysis target data may be performed when necessary. This may be performed by the user, or the data analyzing device 1 may perform the portion that can be executed by the data analyzing device 1. For example, missing value removal and filling processing that removes a random missing value and adds a missing item, replacement processing that replaces an existing value with another value, deletion processing that deletes a random column, addition processing that adds a random column, numerical expression input processing that inputs a random numerical expression in a cell, information addition processing that adds predetermined information to a random column, etc. can be performed. The analysis target data can be processed by such processing. Therefore, the data analyzing device 1 can perform ETL processing and by performing the ETL processing, the analysis target data can be transformed into a form more suitable for analysis. As a result, the accuracy of the analysis result can be further improved. When the ETL processing is completed, it is possible to proceed to the next step by operating a completion button and the like on the user interface which is not shown in the drawings. It is also possible to proceed to the next step without performing the ETL processing.

The above is the processing executed in step SB1 in the flowchart shown in FIG. 5. Thereafter, the process proceeds to step SB2 and the relation between tables is defined. The definition of the relation between the tables is executed by the user of the data analyzing device 1. When the control unit 10 detects that the reading of the analysis target data, or the ETL processing of the analysis target data after reading has been completed, the control unit 10 generates a user interface for relation definition 51 shown in FIG. 6 to display on the monitor 3 and receives the user's operation performed on the user interface for relation definition 51.

The user interface for relation definition 51 is provided with a first table name display region 51 a and a second table name display region 51 b which display the names of two tables forming a set. Further, the user interface for relation definition 51 is provided with a first attribute selection region 51 c which selects and displays one of a plurality of attributes included in the table displayed in the first table name display region 51 a, and a second attribute selection region 51 d which selects and displays one of a plurality of attributes included in the table displayed in the second table name display region 51 b. The first attribute selection region 51 c and the second attribute selection region 51 d may be configured, for example, in a form of a pull-down menu, and by clicking each of them, it is possible to display the names of the plurality attributes included in each table in a list and to select a desired attribute therefrom. The selected attribute is an attribute specified by the user, and only the name of the specified attribute is displayed in the first attribute selection region 51 c and the second attribute selection region 51 d while the names of the attributes that are not specified are not displayed.

As shown in an example in the user interface for relation definition 51, the definition of the relation between the tables is carried out by specifying the names of the attributes respectively for the set of tables (customer table and order table). As shown in FIG. 7, lines in which the values of the specified attributes match are considered to correspond to each other. In the example shown in FIG. 7, examples that “user 001” of “customer table” corresponds to “user 001” of “order table”, “user 002” of “customer table” corresponds to “user 002” of “order table”, and “user 004” of “customer table” corresponds to “user 004” of “order table” are indicated by relation lines L.

In a case of a relational database, the correspondence between table attributes may have already been defined on the database side. The correspondence defined on the database side is called foreign key constraint. When there is a foreign key constraint, the already set correspondence may be read by the data analyzing device 1 side in step SB1 and the data analyzing device 1 may automatically set the definition of the relation between the tables.

When the relation between the tables is defined as described above, the data analyzing device 1 automatically determines multiplicity for each correspondence. Automatic determination of multiplicity is performed by the control unit 10. As shown in FIG. 8, there are three types of multiplicity, i.e., 1:1 type, 1:N type, and N:N type, and it can be determined by referring to the contents of the tables. The 1:1 type is a relation in which one line of one table corresponds to one line of the other table. The 1:N type is a relation in which one line of one table corresponds to a plurality of lines of the other table. The N:N type is a relation in which one line of a table corresponds to a plurality of lines of the other table and one line of the other table corresponds to a plurality of lines of the one table.

The above is the processing executed in step SB2 of the flowchart shown in FIG. 5. Thereafter, the process proceeds to step SB3 to perform a processing of automatically generating an objective variable candidate. The processing of automatically generating an objective variable candidate is a processing performed by the objective variable candidate generating unit 14 shown in FIG. 2, and first, the objective variable candidate generating unit 14 reads the result recognized by the type recognizing unit 13 shown in FIG. 2.

In step SB3 a in the flowchart shown in FIG. 5, the objective variable candidate generating unit 14 sets at least one attribute that is a numeric type recognized by the type recognizing unit 13 as an attribute of an aggregation target, sets at least one attribute that is a category type recognized by the type recognizing unit 13 as an attribute of an aggregation unit, and aggregates, for each category value of the attribute of the aggregation unit, a numeric value of the attribute of the aggregation target based on a previously prepared aggregation function to automatically generate a new objective variable candidate. The objective variable is an attribute that the user of the data analyzing device 1 wants to predict. The aggregation function is a function applied for aggregating a plurality of attribute values of an attribute (purchase amount, etc.) of an aggregation target for an aggregation unit (gender, user, etc.), and a total (SUM), an average (AVE) and the like are generally used. However, other functions may also be used.

In addition, the objective variable candidate generating unit 14 may also be configured to set at least one attribute that is a numeric type recognized by the type recognizing unit 13 as an attribute of an aggregation target, set at least one attribute that is a numeric type recognized by the type recognizing unit 13 as an attribute of an aggregation unit, and aggregate, for each numeric value of the attribute of the aggregation unit, a numeric value of the attribute of the aggregation target based on a previously prepared aggregation function to automatically generate a new objective variable candidate.

Further, the objective variable candidate generating unit 14 may also be configured to set, regardless of the result of recognition by the type recognizing unit 13, at least one attribute as an attribute of an aggregation target, set at least one other attribute as an attribute of an aggregation unit, and aggregate, for each attribute value of the attribute of the aggregation unit, an attribute value of the attribute of the aggregation target based on a previously prepared aggregation function to automatically generate a new objective variable candidate. In this case, the type recognizing unit 13 can be omitted.

The objective variable candidate generating unit 14 will be described in detail below. The objective variable candidate newly generated by the objective variable candidate generating unit 14 is an objective variable candidate automatically generated based on a combination of the attributes included in the analysis target data and the aggregation function. Although the details will be described later, when there is a plurality of objective variable candidates, the user can select a desired one from these objective variable candidates and set the selected objective variable candidate as an objective variable.

The objective variable candidate generating unit 14 searches for objective variable candidates based on the table input to the data input unit 12 and the definition information of the relation between the tables, and stores the objective variable candidates in a candidate storing unit 30 a shown in FIG. 2. The objective variable candidates can be roughly divided into four types: 1. an original attribute value; 2. a value obtained by converting an original attribute value into a flag; 3. a value obtained by aggregating an original attribute value per group of another attribute value; and 4. a value obtained by aggregating a table per group of another table. Each of them will be described below.

1. Original Attribute Value

As shown in FIG. 9, original attribute values are attributes included in the analysis target data input to the data input unit 12, and one of them can be treated as an objective variable candidate. Since it is necessary to provide an objective variable in a numeric value in machine learning, here only variables of numeric type will be the target.

2. Value Obtained by Converting Original Attribute Value into Flag

The value obtained by converting an original attribute value into a flag is a value converted into binary information by applying a predetermined conditional expression to an original attribute included in the analysis target data input to the data input unit 12. The converted information can be set as the objective variable candidate. Regarding the method of applying the conditional expression, as shown in FIG. 10, when the type of an attribute value is a category type (for example, gender), conversion to binary information may be performed based on whether the value of the attribute matches a certain value. In this example, “male” is “1”, and “female” is “0”. In addition, regarding the method of applying the conditional expression, when the type of an attribute value is a numeric type (for example, age), conversion to binary information may be performed based on whether the value of the attribute is more than a certain value/less than a certain value/a certain value. In the case of a numeric value, a plurality of methods of setting thresholds can be considered, and statistics such as “average value” and “modal value” may be automatically selected as the thresholds. Also, the user may specify a random threshold. In this case, a threshold input unit may be provided. In addition, in the case of categorical variables, when there is a plurality of types of values, only high frequent values may be automatically selected.

3. Value Obtained by Aggregating Original Attribute Value Per Group of Another Attribute Value

The value obtained by aggregating an original attribute value per group of another attribute value is a value obtained by grouping the values of the attributes of an aggregation target for each type of the other attributes and applying an aggregation function for each group. Combinations of the following four conditions a) to d) are tried exhaustively and are obtained as objective variable candidates.

Condition Possible value a) Attribute of aggregation All attributes of numeric target type b) Attribute that is All attributes of category aggregation unit type or attributes used for relation definition c) Type of aggregation Predefined function set (for function example, SUM, AVG) d) Condition for aggregation Automatically generated (optional) condition set (for example, weekly, monthly), or setting by user

When a condition is specified for a table unrelated to a) and b), it will be ignored.

Taking the tables shown in FIG. 11 as an example, a line L1 connecting the attribute “user” of the customer table and the “user” of the order table indicates that the relation between the tables is defined in step SB2 in the flowchart shown in FIG. 5. Further, “1” and “N” at both ends of the line L1 represent multiplicity, and it is 1 when there is no repetition while it is N when there is repetition. In this case, “age” and “purchase amount” correspond to numeric type attributes and “user” and “gender” correspond to category type attributes, and these are recognized by the type recognizing unit 13.

For conditions of aggregation, for example, when there is a date type attribute (here, “purchase date”) as a type of attribute values, a plurality of conditions such as the latest one month and the latest one week are automatically generated for the attribute. That is, the objective variable candidate generating unit 14 is configured to automatically generate a predetermined period as an aggregation condition when the analysis target data input to the data input unit 12 includes a date type attribute. The predetermined period may be set to any period, and can be set by, for example, year-month-date or time. Here, conditions may be automatically sorted out from actual attribute values. For example, when the actual attribute values are concentrated in a predetermined period, periods exceeding the predetermined period are excluded. To be specific, when the actual attribute values are concentrated in the range of two weeks, the condition “the latest one month” is excluded.

Here, when the aggregation function is of two types, SUM (total) and AVE (average) and the aggregation condition is of two types, “whole period” and “purchase date after 2019/1/1”, as shown in FIG. 12, in all, 2×2×2×2=16 candidates are generated.

However, with regard to candidates 3 and 4 shown in FIG. 12, it is known from the multiplicity that there is always one type of the aggregation target (gender, age) with respect to the aggregation unit (user), and thus these candidates are deleted. Namely, it is possible to determine the number of types of the aggregation targets based on the multiplicity, and as a result of the determination, when the number of types of the aggregation targets is equal to or less than a predetermined number, to delete the candidates. Further, with regard to the candidates 9 to 12 shown in FIG. 12, the attributes of a) and b) are completed in the customer table and are not related to the conditional expression of d). Therefore, the candidates 9 to 12 are deleted. As a result, the remaining ten candidates (candidates 1, 2, 5 to 8, and 13 to 16) are added to the objective variable candidates.

Here, the aggregation unit b) is a single attribute. However, the objective variables may also be generated by aggregation by a plurality of combinations. In that case, for example, objective variables such as “purchase amount per prefecture×year” and “sales amount per store×month” may be defined.

In generating candidates of objective variables, the following SQL text is generated inside the data analyzing device 1.

SELECT SUM (GENDER) FROM ORDER TABLE WHERE PURCHASE DATE>=‘2019-01-01’ GROUP BY USER;

In order to make it easy to understand when presenting to the user, by applying it to a template such as

{aggregation function} of {condition} per {aggregation unit} {aggregation target},

an expression of natural language is also automatically generated. The natural language expression and the actual generation method (SQL) may be associated and stored in the storing unit 30.

4. Value Obtained by Aggregating Table Per Group of Another Table

In this case, aggregation is performed with respect to the table, not to the attribute. There are two types of aggregation methods, “the number of lines of a table” and “whether there is a line in a table”, and aggregation is executable by obtaining the information.

Condition Possible value a) Table of aggregation All tables target b) Attribute that is All attributes of category aggregation unit type or attributes used for relation definition c) Type of aggregation Predefined function set (for function example, number of lines, presence/absence) d) Condition for aggregation Automatically generated (optional) condition set (for example, weekly, monthly), or setting by user

Taking the table shown in FIG. 13 as an example, the line L1 connecting the attribute “user” of the customer table and the “user” of the order table is the same as that shown in FIG. 11. Similar to the above “3. Value obtained by aggregating original attribute value per group of another attribute value”, candidates 1 to 8 shown in FIG. 14 remain when aggregations having a multiplicity of 1 are deleted. For example, the candidate 6 is an indicator of “customer defection” often used in marketing, and is useful in data analysis.

All applicable ones among the above 1 to 4 are applied to all attributes of all tables input by the user of the data analyzing device 1, and each of them is stored as an objective variable candidate in the candidate storing unit 30 a shown in FIG. 2. In the aforementioned example, as shown in FIG. 15, 22 objective variable candidates are automatically generated.

The above is the processing executed in step SB3 in the flowchart shown in FIG. 5. Thereafter, the process proceeds to step SB4 and a feature value is automatically generated. The generation of the feature value is substantially the same processing as the generation of the objective variable candidate, and may be performed together with the generation of the objective variable candidate in step SB3. In addition, although the generation of the feature value is performed by the feature value automatic generating unit 15 shown in FIG. 2, it may also be performed by the objective variable candidate generating unit 14.

The feature value automatic generating unit 15 is configured to automatically generate a new feature value by applying a predetermined function to the original attribute or a combination of a plurality of attributes included in the analysis target data. The feature value is synonymous with an explanatory candidate, and is an attribute used to describe an objective variable. Details of the automatic generation of a feature value will be described later.

In step SB5 in the flowchart shown in FIG. 5, scoring of an objective variable candidate is performed. The scoring of the objective variable candidate is to calculate a score representing the usefulness of the objective variable candidate, and is performed by the score calculating unit 16 shown in FIG. 2.

In the above examples (examples shown in FIG. 11 and FIG. 13), each of the two tables (the customer table and the order table) has only three attributes. However, in actual analysis data, there are more data targets, and thus a large number of objective variable candidates are generated. For example, when there are 20 numeric type attributes and 20 category type attributes, and the aggregation period is of three types, “whole period”, “one year”, and “half a year”, with the aggregation functions of “average”, “total”, “maximum”, and “minimum”, the objective variables obtained by aggregating the attributes will be 20×20×4×3=4800 types.

Accordingly, it is difficult for the user to obtain a desired objective variable only by presenting all the generated objective variable candidates. Therefore, in step SB5 in the flowchart shown in FIG. 5, a score indicating the usefulness for the user is calculated for the objective variable candidate generated in step SB3. For example, by presenting the score values in descending order to the user or presenting only the score values that are equal to or greater than a predetermined value, the user can quickly start a desired analysis.

As a method of score calculation, for example, the following indicators 1 to 7 or any combination of these indicators may be used. However, the method is not limited thereto.

1. Number of Lines of Generated Objective Variables

The score calculating unit 16 may be configured to calculate the score based on the number of lines of the generated objective variables. That is, that how many lines of objective variables are generated differs by objective variable candidates. For example, in the example shown in FIG. 15, in the case of “total purchase amount per gender”, only two lines (male and female) of objective variables are generated. In a case of performing data analysis by supervised learning, it is generally known that accurate analysis cannot be performed when the number of data is too small. For this reason, in the case where only two lines of data are generated as described above, it is expected that no meaningful results will be obtained even if an analysis is conducted. Therefore, usefulness can be expressed by scoring the number of lines of the generated objective variables. That is, the smaller the number of lines of the generated objective variables, the lower the score is; the greater the number of lines of the generated objective variables, the higher the score is.

2. Variance of Generated Objective Variables

The score calculating unit 16 may be configured to calculate a score based on a variance of the generated objective variables. That is, in the case of performing data analysis by supervised learning, when all the values of the objective variables become the same value, it is impossible to make a meaningful calculation. This is because the optimal solution is to always output a constant while ignoring all the values of the explanatory variables. Therefore, the variance of the generated objective variables is reflected in the score, thereby lowering the score of such a case. In a word, the smaller the variance, the lower the score.

3. Whether Attribute Used for Defining Relation Between Tables is Aggregation Unit or not

The score calculating unit 16 may be configured to calculate a score based on an attribute used for defining a relation between tables. That is, in a case of creating objective variables by aggregating per attribute, either of 1) a categorical variable and 2) an attribute used for relation definition may be used as the aggregation unit. In general, attributes used for defining the relation between tables often have important grading in business, such as “user” and “item”. Therefore, the attribute used for defining the relation between tables is obtained and a higher score is given to the objective variable using the attribute used for relation definition.

4. Number of Records in Each Group

The score calculating unit 16 may be configured to calculate a score based on the number of records (number of data) in a group. That is, in the generation of objective variable candidates, cases where there is only one record in each group, such as “average age per user”, is excluded. Even if it is not a self-evident case like this, when the number of records in the group is small, it is often not useful even calculating the average value. Therefore, for an objective variable using an average value, the number of records in each group is also taken into account to calculate the score. The greater the number of records, the higher the score is; the smaller the number of records, the lower the score is. In this case, record number acquiring means for acquiring the number of records may be provided.

5. Similarity to Objective Variables that have been Selected in the Past

The score calculating unit 16 may be configured to calculate a score based on the degree of similarity to objective variables that have been selected in the past. That is, it is presumed that the objective variables that have been used by the user are very likely to be used again. Therefore, for example, the following score criteria may be used. In this case, an objective variable that has been used in the past is stored in the storing unit 30 shown in FIG. 2, and when calculating the score, it is only necessary to read the objective variable that has been used in the past from the storing unit 30.

Score=1: If it matches any one of the objective variables that have been used in the latest N times

Score=0: else

Alternatively, the number of times of being used for objective variables among the latest N times may be defined as the latest adoption rate and it may be combined with the adoption rate for each component of the objective variables.

Score=latest adoption rate of aggregation target×latest adoption rate of aggregation unit×latest adoption rate of aggregation function

When the data analyzing device 1 is provided as a system available to a plurality of users, it is possible to give a high score to an objective variable adopted by another user in the same data. For example, it is only necessary to associate a user and an objective variable adopted by the user and store in the storing unit 30 shown in FIG. 2, and to read the information from the storing unit 30 when calculating the score. In this case, it is possible to use a machine learning method known as a general recommendation algorithm such as collaborative filtering.

6. Name of Attribute

The score calculating unit 16 may be configured to calculate a score based on the name of an attribute. That is, a score is added when the name of the attribute includes characters having meanings that are easy to be used for objective variables in data analysis, such as “unit price”, “sales”, “defective products”, and “defection”. As to how many scores should be added for what kind of name, it may be done by collating a correspondence table generated in advance on the system side, or machine learning may be used to directly calculate the score from the name of the attribute.

7. Percentage of Missing Values

The score calculating unit 16 may be configured to calculate a score based on the percentage of missing values. In the case of calculating an average value, the value of the objective variable cannot be defined when there are no records to be aggregated in a target group. Such a case is called missing values, and it is necessary to fill in with appropriate values, such as 0, for each problem, or exclude missing lines from the analysis. When the percentage of missing values is high, the reliability of the analysis decreases. Therefore, the score is lowered as the number of missing values increases.

Score=100−percentage of missing values in objective variable (%)

The above is the processing executed in step SB5 in the flowchart shown in FIG. 5. Then, the process proceeds to step SB6 to refine the objective variables. The refining of the objective variables means that a user refines the desired objective variables from the plurality of objective variable candidates generated in step SB3, and this may be performed by the keyword input unit 18 and the attribute selecting unit 19 shown in FIG. 2. The keyword input unit 18 generates a user interface for keyword input 54 shown in FIG. 16 to display on the monitor 3 and receives the user's operation performed on the user interface for keyword input 54.

The user interface for keyword input 54 is provided with an input region 54 a where the user can input a text such as a search keyword, and a candidate display region 54 b. Information input to the input region 54 a is keyword information, and may be keyword information containing one word as shown in FIG. 16A, or may be keyword information containing two or more words as shown in FIG. 16B. It is possible to input a plurality of pieces of keyword information.

The input region 54 a is configured to receive a text input from the user, that is, an input of keyword information. When the text input is received, the objective variable candidate generating unit 14 searches a natural language expression of the objective variable candidate that matches the input from among the plurality of objective variable candidates generated in step SB3 in the flowchart shown in FIG. 5. The objective variable candidate generating unit 14 is configured to generate in advance a list of objective variable candidates and extract objective variable candidates related to the keyword information input by the user via the keyword input unit 18 from the list.

Specific examples will be described based on FIGS. 16A and 16B. In the example shown in FIG. 16A, one word is input, and thus objective variables containing the word are searched. In the example shown in FIG. 16B, two words are input, and thus objective variables containing the two words are searched. In the search, a fuzzy match search (for example, purchase price and purchase amount) based on word similarity and the like may be performed for an input that does not completely match the objective variable candidates. In addition, it may be configured to be capable of selecting between AND search and OR search.

In the candidate display region 54 b, objective variable candidates including the text input by the user are displayed as a search result. Since this is displayed on the monitor 3, the monitor 3 displays new objective variable candidates generated by the objective variable candidate generating unit 14 and also displays objective variable candidates (objective variable candidates extracted from the list) related to the keyword information input by the user via the keyword input unit 18. When it is not necessary to refine the objective variables, the new objective variable candidates generated by the objective variable candidate generating unit 14 may be displayed on the monitor 3 without performing a text search. The new objective variable candidates generated are displayed on the monitor 3, and thus the user can easily grasp the objective variable candidates.

In the candidate display region 54 b, the objective variable candidates are displayed in descending order of scores calculated by the score calculating unit 16. The objective variable candidates may be arranged and displayed in a ranking format where the higher the score, the higher the objective variable candidate ranks. As a result of the search, when there are many objective variable candidates, only the objective variable candidates having the scores ranking high among the scores calculated by the score calculating unit 16 may be displayed in the candidate display region 54 b. In this case, the number of displayable objective variable candidates can be set to about five or ten. In a word, the monitor 3 may be configured to be capable of displaying an objective variable candidate having a score calculated by the score calculating unit 16 equal to or greater than a predetermined value, and in this case, the number of the displayed objective variable candidates may be set as a predetermined number.

The monitor 3 can simultaneously display the original attribute of the analysis target data input to the data input unit 12 and the new objective variable candidate generated by the objective variable candidate generating unit 14. The monitor 3 can also be configured to display a value obtained by converting the attribute value of the original attribute of the analysis target data input to the data input unit 12 into a flag.

In addition, means for allowing the user to edit a column name of the generated objective variables may be provided. That is, the keyword input unit 18 generates a user interface for editing 55 shown in FIG. 17 to display on the monitor 3 and receives the user's operation performed on the user interface for editing 55. The user interface for editing 55 is provided with an editing target input region 55 a to input a column name of an objective variable to be edited, and a column name input region 55 b to input a changed column name. When “average purchase amount per user” is input in the editing target input region 55 a and “unit purchase price” is input in the column name input region 55 b, the column name of the objective variable is changed to “unit purchase price”. This makes it easier to understand the results of data analysis.

The attribute selecting unit 19 shown in FIG. 2 is a part that receives a selection input from the user regarding an attribute of an aggregation target or an aggregation unit, and is, similar to the keyword input unit 18, configured to be capable of selecting and inputting an attribute. In this case, an objective target candidate generated by using the attribute input by the user via the attribute selecting unit 19 as an aggregation target or an aggregation unit is displayed on the monitor 3.

Either of the generation of the objective variable candidate by the objective variable candidate generating unit 14 and the reception of the input from the user regarding the attribute of the aggregation target or the aggregation unit may be first. When the input from the user regarding the attribute of the aggregation target or the aggregation unit is received after the generation of the objective variable candidate by the objective variable candidate generating unit 14, it is possible to extract from the generated objective variable candidates the objective variable candidate generated using the attribute input by the user as the aggregation target or the aggregation unit to display on the display unit. When the input from the user regarding the attribute of the aggregation target or the aggregation unit is received before the generation of the objective variable candidate by the objective variable candidate generating unit 14, it is only necessary that the objective variable candidate generating unit 14 generates an objective variable candidate using the attribute input by the user as the aggregation target or the aggregation unit and the generated objective variable candidate is displayed on the display unit.

The selection receiving unit 20 shown in FIG. 2 is a part that receives a selection of an objective variable by the user from among the objective variable candidates displayed on the monitor 3. Specifically, it is configured to be capable of detecting which one is selected by the user from the objective variable candidates displayed in the candidate display region 54 b of the user interface for keyword input 54 shown in FIG. 16. For example, by arranging the pointer of the mouse 5 so as to overlap with one of the objective variable candidates displayed in the candidate display region 54 b and clicking, the objective variable can be selected, and an objective variable may also be selected by operating the keyboard 4 and the like. The selection receiving unit 20 can also be configured to be capable of selecting a plurality of objective variables.

When the original attribute and the new objective variable candidate are displayed on the monitor 3, the selection receiving unit 20 can receive a selection of an objective variable by the user from the original attribute and the new objective variable candidate. When the original attribute, the new objective variable candidate, and the value converted into a flag are displayed on the monitor 3, the selection receiving unit 20 can receive a selection of an objective variable by the user from the original attribute, the new objective variable candidate, and the value converted into a flag. The candidate display region 54 b may display a plurality of objective variable candidates, and may also display only one objective variable candidate. However, in either case, it is configured to receive the selection of the objective variable by the user.

The above is the processing executed in step SB6 in the flowchart shown in FIG. 5. Thereafter, the process proceeds to step SB7 to perform preview display. In the preview display, for the objective variable selected by the user in step SB6, the objective variable is actually calculated using the analysis target data and the result is displayed as preview. The control unit 10 generates, for example, a user interface for preview display 56 shown in FIG. 18 to display on the monitor 3. The user interface for preview display 56 is provided with an objective variable display region 56 a which displays the objective variable selected by the user, a preview display region 56 b which displays the result of the actually performed calculation of the objective variable, and an analysis start button 56 c. The result displayed in the preview display region 56 b may be a calculation result using only a part of data (10% of all data in the present example) when the data amount is large. The amount of data used for the calculation may be displayed in the user interface for preview display 56 so that it can be known by the user.

By the processing of step SB6, it is possible to display only a part of the analysis results on the monitor 3 as preview display before the generation of a prediction model by the analyzing unit 21. By preview display, it is possible to confirm before analysis execution whether this is the user's intended analysis content.

When it is the user's intended analysis content, the user presses the analysis start button 56 c of the user interface for preview display 56. As a result, the process proceeds to step SB8 in the flowchart shown in FIG. 5. When it is not the user's intended analysis content, the process can return to step SB6 and another objective variable candidate can be selected.

In step SB8, the objective variable selected by the selection receiving unit 20 is used to perform an actual data analysis using a prediction model. A known machine learning method (for example, AutoWEKA, etc.) may be used to select an optimal one from a plurality of prediction models. This is performed by the analyzing unit 21 shown in FIG. 2. The analyzing unit 21 is configured to be capable of generating a prediction model for predicting the objective variable selected by the selection receiving unit 20 using the new feature value generated by the feature value automatic generating unit 15. For example, it is possible to generate a prediction model for predicting an objective variable from a plurality of feature values, and this prediction model can be created by, for example, multiple regression analysis or a decision tree. There are various generation methods, and any of the methods that are conventionally known may be used.

(Automatic Generation of Feature Value)

For example, in a case where the objective variable is “sum of purchase amount per user”, when the “sum of purchase amount per user” is also created in the feature value, an analysis result in which all other feature values are ignored is obtained and it is not possible to obtain a meaningful analysis result. Such a situation in which the information of the objective variable is unintentionally “leaked” to the feature value is called a leak, and this tends to happen on analysts who are not skilled in machine learning.

In order to prevent the leak, the feature value automatic generating unit 15 is configured to automatically generate a new feature value by applying a predetermined function to attributes excluding at least a part of attribute values of attributes of the aggregation target used by the objective variable candidate generating unit 14 when generating an objective variable selected by the selection receiving unit 20. Therefore, when the user selects an objective variable, a new feature value is automatically generated. In this case, a predetermined function is applied to attributes excluding at least a part of attribute values of attributes of the aggregation target used when generating an objective variable by the objective variable candidate generating unit 14, and thus a situation in which the information of the objective variable is unintentionally leaked to the feature value is avoided.

The feature value automatic generating unit 15 may also be configured to automatically generate a new feature value by applying a predetermined function to the original attribute or a combination of a plurality of attributes included in the analysis target data, and exclude from the generated feature values the feature value including information of at least a part of attribute values of attributes of the aggregation target used for the objective variable selected by the selection receiving unit 20 to generate a final feature value. In this case, a feature value including the information of at least a part of attribute values of attributes of the aggregation target used for the objective variable is excluded to obtain the final feature value, and thus a situation in which the information of the objective variable is unintentionally leaked to the feature value is avoided. Therefore, the situation in which the information of the objective variable is unintentionally leaked to the feature value (leak) can be automatically prevented even for those who are not skilled in machine learning.

Configurations that can be provided in the data analyzing device 1 as means for preventing a leak will be described in detail below.

1. Use Only Data Prior to a Period Used to Aggregate Objective Variables

In step SB3 in the flowchart shown in FIG. 5, when the aggregation condition of the objective variables is set by date, the analysis target data prior to the date is not used for the objective variables, and thus no leaks occur even if it is used for calculating the feature value. Therefore, it is determined whether a date is specified in the aggregation condition. When a date is specified, it is made such that the period as the aggregation condition of the objective variables does not overlap with the period of the analysis target data used for calculating the feature value, and only the analysis target data prior to the date of the aggregation condition at the time of the generation of the feature value is used. Accordingly, as shown in FIG. 19, for example, when “average purchase amount of 2019/1 per user” is set as the objective variable, “average purchase amount of 2018/12 per user” prior to “average purchase amount of 2019/1 per user” can be generated as the feature value. Namely, the feature value automatic generating unit 15 may be configured to automatically generate a feature value by excluding attribute values in the corresponding period of the aggregation target when the aggregation condition of the objective variables is set by date, and to be specific, a feature value is automatically generated by using only the analysis target data prior to that date.

2. Do not Use Attributes/Tables which are Aggregation Targets of Objective Variables for the Feature Value

The feature value automatic generating unit 15 may be configured to determine whether a date is specified in the aggregation condition of objective variables and, when a date is not specified, to exclude the attribute itself used for the objective variables from the generation target of the feature value. The aforementioned method 1 cannot be used when a date is not specified in the aggregation condition of the objective variables. In that case, the attribute itself used for the objective variables is excluded from the generation target of the feature value. In this way, the situation in which the information of the objective variable is unintentionally leaked to the feature value is avoided. In this case, it is only necessary to make the attribute used for the objective variable read from the storing unit 30 and the like.

3. Match Objective Variables with the Aggregation Period

The aggregation period of the analysis target data used in the generation of the objective variable candidate by the objective variable candidate generating unit 14 and the aggregation period of the analysis target data used in the generation of the feature value by the feature value automatic generating unit 15 can be matched. For example, when the objective variable is “total sales per store of 2019/1”, it can be inferred that the user of the data analyzing device 1 is interested in the aggregation on a monthly basis. As a result, it is also inferred for the feature value that it is effective to add the feature value aggregated in one month, such as “total sales per store of 2018/12 (previous month)” and “total sales per store of 2018/1 (same month in previous year)”, and thus a feature value aggregated in such a period is generated. Similarly, when “total sales of 2019/1/1 to 1/8” is the objective variable, a feature value aggregated on a weekly basis is automatically generated. It takes time to try the period of aggregation in a round-robin format. In contrast, by generating a feature value in accordance with the time unit instructed by the user, it is possible to quickly obtain a result which is easier to interpret for the user.

FIG. 20 shows a user interface for result display 57. The user interface for result display 57 is generated by the control unit 10 and displayed on the monitor 3. The user interface for result display 57 is provided with an objective variable display region 57 a to display an objective variable, and a segment display region 57 b to display a segment. The segment is a subset of data extracted by applying a line extraction condition to analysis target data, and can also be called a combination of an attribute and the condition.

Alternative mode of objective variable refining method

In step SB6 in the flowchart shown in FIG. 5, the objective variable candidates generated in step SB3 are refined. However, the method is not limited to the above-described method, and the following method may also be used. That is, it may be configured to be capable of receiving a stepwise selection in refining the objective variables. In a first stage, as shown in FIG. 21A, the selection of the attribute which is the aggregation unit for the objective variables is received. Options presented here are attributes selected as aggregation units for at least one of all of the objective variable candidates generated in step SB3. FIG. 21A shows a user interface for refining 60, and the control unit 10 generates the user interface for refining 60 to display on the monitor 3. The user interface for refining 60 is provided with an attribute selecting unit 60 a with a pull-down menu form to receive the selection of the attribute which is the aggregation unit, a BACK button 60 b, and a NEXT button 60 c. After selecting the attribute by the attribute selecting unit 60 a, the process proceeds to a second stage by pressing the NEXT button 60 c.

In the second stage, as shown in FIG. 21B, among all objective variable candidates, only objective variables that have the attribute selected in the first stage as the aggregation unit are presented in an order of score. This is displayed in a score order display region 60 d provided in the user interface for refining 60. A selecting unit with a pull-down menu form which receives the selection of the objective variable is provided in the score order display region 60 d and can receive the selection of the objective variable. As a result, it is possible to quickly select an objective variable that matches the grading that the user wants to analyze from a plurality of objective variable candidates. After selecting the objective variable, the process proceeds to a third stage by pressing the NEXT button 60 c.

In the final third stage, specification of an alias for displaying the analysis result in an easy-to-understand manner is received for the selected objective variable. As shown in FIG. 21C, the user interface for refining 60 is provided with an alias specification region 60 e in which an alias can be input. When the user inputs an alias in the alias specification region 60 e, the name of the objective variable selected in the second stage is changed to the input alias.

In this example, first the candidates for all aggregation units are generated in step SB3 and then the selection by the user is received in step SB6. However, this order may be reversed. That is, it is also possible to first receive the selection of the aggregation unit by the user and then to generate only the objective variables that use the attribute as the aggregation unit to present these objective variables in a list to the user. In this way, the number of the generated objective variable candidates can be reduced. Although the selection of the attribute used as the aggregation unit is received here, it is also fine to receive the attribute of the aggregation target instead.

EXAMPLES

Three kinds of examples will be described below regarding a method of holding internal data in each step of the generation processing of the objective variable.

First Example

In the first example, as shown in “1. Input data” in FIG. 22, it is assumed that the user inputs two tables, a customer table and an order table, as analysis target data. The objective variable candidate generating unit 14 generates new attributes combining the attributes based on the input tables (analysis target data) and generates the same as objective variable candidates. In this case, as shown in “2. Generation of objective variable candidate” in FIG. 22, new tables including the objective variables and the aggregation units are generated in the data analyzing device 1.

Next, as shown in “3. Selection of objective variable” in FIG. 22, one table including the objective variable selected by the user is selected from the created new tables. In this example, “average purchase amount per user” generated by the combination of:

attribute of aggregation target: purchase amount (order table),

aggregation unit: user (order table), and

aggregation function: average

is selected.

In the subsequent feature value automatic generating step, new attributes are generated as feature values from the combination of the aggregation function and the attributes based on the three remaining tables in “3. Selection of objective variable”. In this step, as shown in “4. Generation of feature value”, “purchase amount”, which is the attribute of the aggregation target in the objective variables, is excluded from the generation targets of the feature values.

Second Example

In the second example, the user can update the customer table and the order table to the latest state after selecting the objective variable. That is, before an actual data analysis (feature generation to prediction modeling) is started, the value of the attribute of the objective variable is recalculated based on the latest state and data analysis is performed based on the recalculated value. By recalculating for different analysis target data, it is possible to utilize the selected objective variable when performing repeated analysis, such as when performing fixed analysis processing monthly.

“1. Input data”, “2. Generation of objective variable candidate”, and “3. Selection of objective variable” in FIG. 23 are the same as the respective steps in FIG. 22. In the second example, there is a step of “4. Update of analysis target data”, in which the lightly shaded cells are places updated from the step of “3. Selection of objective variable”.

Third Example

In the third example, when generating objective variable candidates, instead of generating actual attributes and attribute values, as shown in the step of “2. Generation of objective variable candidate” in FIG. 24, combinations of aggregation target and aggregation unit and aggregation function, corresponding natural language expressions, and SQL texts are stored. This can be stored in the storing unit 30 shown in FIG. 2.

Then, as shown in “3. Selection of objective variable” in FIG. 24, when an objective variable is selected according to the specification of the user, the aforementioned SQL text is applied to the actual data, and as shown in “4. Execution of SQL”, a table including the objective variable is generated. Similar to the second example, the attribute values of the target tables may be updated before actually applying the SQL text. As a result, by holding only the combination method without generating the attribute value of the objective variable in the step of “2. Generation of objective variable candidate”, it is possible to reduce the amount of data to be generated and to speed up processing.

Automatic Segmentation Function

The data analyzing device 1 has an automatic segmentation function. The automatic segmentation function is a function that can be executed as needed, for example, a function which can automatically extract from the analysis target data a group in which objective variables have a similar tendency and can present extraction conditions (feature values automatically generated and conditions thereof) and various statistics to the user. The automatic segmentation function is, for example, a function executed by an evaluating unit 40 shown in FIG. 2. For each of a plurality of feature values, by determining a division point indicating a change in influence on an objective variable, each feature value is divided into a plurality of segments and an evaluation value is calculated using an influence degree of each segment on the objective variable as an index.

The details will be described below. FIG. 25 is a flowchart showing a processing procedure executed by the automatic segmentation function. The automatic segmentation function may be started after receiving an instruction from the user, or may be automatically started at a timing determined by the data analyzing device 1. In step SC1 after starting, an optimal division point is searched.

When searching for an optimal division point, a calculation is performed in the following steps with respect to input feature values and objective variables.

Procedure 1. Select any one of a plurality of feature values.

Procedure 2. Divide the analysis target data into two at a candidate point where analysis target data is divided into two, and calculate an evaluation value for each set after the division.

Procedure 3. Store the division point where the evaluation value is optimal from the calculation result of Procedure 2 for the feature value.

Procedure 4. Repeat Procedures 1 to 3 for all feature values.

The above procedures are equivalent to an algorithm for determining division points in algorithms generally called a decision tree. For the evaluation value used in Procedure 2, the same one as a general evaluation value in the decision tree may be used.

When the objective variable is binary (0/1), for example, Information Gain represented by the expression shown in the upper side of FIG. 26 may be used. When the objective variable is a continuous value, for example, Variance Reduction represented by the expression shown in the lower side of FIG. 26 may be used. Therefore, the evaluating unit 40 is configured to search for and determine a division point where the evaluation value is optimal.

When the process ends at Procedure 4, information as shown in FIG. 27 is recorded in one line per feature value. The information may be stored in the storing unit 30 shown in FIG. 2. The information shown in FIG. 27 is an example and includes a feature value, a conditional expression, an evaluation value, a share, and an average value (average numeric value) of objective variables after division. However, other information may also be included. The direction of the sign of inequality in the conditional expression is determined so as to leave a previously set group among a group having a high value of objective variables and a group having a low value of objective variables. The evaluation value is a value obtained by the aforementioned expression. The share means a share of data included in segments (group). The share can be obtained by calculating the ratio between the number of data belonging to the group and the total number of data by the evaluating unit 40. The average value of the objective variables after division can also be calculated by the evaluating unit 40.

The above is the processing performed in step SC1 in the flowchart shown in FIG. 25. Next, the process proceeds to step SC2 to perform a simplification processing of the division point. The boundary value of the conditional expression obtained in step SC1 is a halfway value and is often difficult to be used for a measure. Therefore, in step SC2, the boundary condition of the conditional expression is simplified and the average value of the evaluation value and the objective variables after division is recalculated under a simplified condition. The result of recalculation is shown in FIG. 28. The simplification processing can be implemented, for example, by a method of rounding to one significant digit, and the degree of simplification may be set by the user. Examples of the simplification processing include rounding off, rounding up, rounding down, and rounding such that the evaluation value does not decrease.

Next, the process proceeds to step SC3 in the flowchart shown in FIG. 25. In step SC3, processing of deleting duplicate segments is performed. In the present example, a feature value is automatically generated and is divided into segments, and thus there is a high possibility that the segments are duplicated and the processing of deleting the duplicate segments is useful. For example, a segment A extracted under a feature value condition and a segment B extracted under another feature value condition may actually refer to the same group. Therefore, when a duplication degree defined by the following evaluation value exceeds a certain threshold, one of the segments A and B is deleted from the table.

Duplication degree=N(A∧B)/N(A∨B) in the expression, N(P): number of data of P

The segment to be deleted may be determined based on the magnitude of the evaluation value, and in this case, the segment having a smaller evaluation value is automatically deleted. Also, the segment to be deleted may be selected by the user.

Thereafter, the process proceeds to step SC4 in the flowchart shown in FIG. 25. In step SC4, processing of displaying important segments among the segments remaining through the processing of step SC3 is performed. In step SC4, the control unit 10 generates a user interface for result display 57 shown in FIG. 29 and displays the same on the monitor 3. The user interface for result display 57 is the same as that shown in FIG. 20; however, the number of feature values is different. The display region of the segments of the feature values for which the evaluations have been calculated by the evaluating unit 40 is incorporated in the user interface for result display 57, and thus the segments of the feature values for which the evaluation values have been calculated by the evaluating unit 40 can be displayed on the monitor 3 to present to the user by displaying the user interface for result display 57 on the monitor 3.

It is possible to selectively display only the segments that are important for conducting an analysis, that is, segments (high-ranking segments) of feature values of which the evaluation values are high, in the display region of the user interface for result display 57. However, it may also be configured such that segments other than the important segments can be displayed as needed. The segments to be displayed in the display region of the user interface for result display 57 may be automatically selected at the data analyzing device 1 side or may be selected by the user. In addition, it may be configured such that the segments of the feature values for which the evaluation values have been calculated by the evaluating unit 40 are preferentially displayed. In this case, the control unit 10 extracts the feature values for which the evaluation values have been calculated by the evaluating unit 40 to display in the display region of the user interface for result display 57. As a result, the share calculated by the evaluating unit 40 and the average value of the objective variables are displayed in the user interface for result display 57.

The number of segments displayed in the display region of the user interface for result display 57 may be one or more, and the number is not particularly limited. When a plurality of segments are displayed, the arrangement order may be a descending order of evaluation values (Information Gain/Variance Reduction) or a descending order of values of the objective variables after division.

A sentence in a form of “A is equal to or greater than B” or “A is equal to or less than B” representing an extraction condition of each segment is displayed in a segment display region 57 b. Although a name of a feature value is substituted for A and a numeric value which is the value of a division point is substituted for B, the sentence may be displayed in other expressions. For example, by automatically determining what unit of each feature value is by the control unit 10 or by obtaining an additional input from the user, expressions such as “age is 50 or lower”, “unit purchase price is 500 or more”, and “number of visits is 5 or more” can be improved respectively to more intuitively understandable expressions such as “age is 50 years or lower”, “unit purchase price is 500 Yen or more”, and “number of visits is 5 times or more”.

The user interface for result display 57 is provided with a detail display button 57 c for each feature value. When the user operates the detail display button 57 c, the process proceeds to step SC5 in the flowchart shown in FIG. 25. In step SC5, the analysis of step SC1 is conducted again on a group of the selected segments. As a result, a combination of a feature value having a high-ranking evaluation value and a conditional expression is extracted and is, as shown in FIG. 30, presented to the user as a combination recommended by the data analyzing device 1. In the example shown in FIG. 30, “age” is selected as a feature value 1, and in this case, the analysis of step SC1 is conducted again on segments that meet a conditional expression 1 among “age”. As a result, “gender” and “unit purchase price” are selected as feature values 2, and a combination of “age” and “gender” and a combination of “age” and “unit purchase price” are presented to the user as recommended combinations. Therefore, the evaluating unit 40 is configured to be capable of determining a division point indicating a change in influence on an objective variable under a compound condition combining a plurality of feature values, and the evaluating unit 40 divides each feature value into a plurality of segments at the determined division point and calculates an evaluation value using an influence degree of each segment on the objective variable as an index. Then, the segments of the feature values for which the evaluation values under the compound condition have been calculated are displayed on the monitor 3. The processing of deleting duplicate segments in step SC3 may also be performed in step SC5 to leave, for example, only one segment for the segments having a high duplication degree.

The user may select a segment displayed in the user interface for result display 57 shown in FIG. 29. When a segment is selected, the control unit 10 detects which segment has been selected and presents to the user a chart showing the relation between a feature value used for the condition of the selected segment and an objective variable. The chart includes, for example, various kinds of graphs, tabulation tables, etc.

An example of the chart is shown in FIG. 31. FIG. 31 shows a user interface for detail display 58, and the control unit 10 generates the user interface for detail display 58 and displays the same on the monitor 3. The user interface for detail display 58 is provided with a chart display region 58 a, a comment display region 58 b, an editing region 58 c, a summary display region 58 d, a segment output button 58 e, and a simulation button 58 f. When there is one condition of the segment, a line graph with respect to the feature value is generated and displayed in the chart display region 58 a. When there are two conditions, as shown in FIG. 32, a cross-tabulation table with respect to two feature values is displayed in the chart display region 58 a. In a word, the monitor 3 is configured to be capable of displaying switching between a first display form (the form shown in FIG. 31) in which a segment having one feature value is displayed and a second display form (the form shown in FIG. 32) in which a segment having a plurality of feature values is displayed.

As shown in FIG. 31, in the line graph displayed in the chart display region 58 a, a portion corresponding to the condition of the segment is highlighted. As a highlighting method, it includes, for example, a method of displaying the portion corresponding to the condition of the segment in a thicker line than other portions, and a method of changing the type of lines or the color of lines between the portion corresponding to the condition of the segment and other portions. Any one of the methods may be used. By highlighting the portion corresponding to the condition of the segment, it is possible to quickly grasp from what data the segment is divided. In addition, the boundary of the division in the displayed graph or table can be automatically adjusted so as to match the division point of the segment.

The feature of the segment generated in natural language is displayed in the comment display region 58 b. This can be generated by the control unit 10.

The editing region 58 c is a region for finely adjusting a boundary condition from requests and the like at the time of determining a measure with respect to the conditions of segments automatically extracted by the data analyzing device 1, and is a region for editing the extraction condition when a new condition is added. The editing region 58 c can receive an operation of the user, and is configured to be capable of changing the conditional expression or adding another conditional expression according to the user's operation, and deleting unnecessary conditional expressions.

The share and the average value are displayed in the summary display region 58 d. The summary display region 58 d can also display the ratio to the whole segments.

The segment output button 58 e is a button for outputting a list of groups corresponding to the segment to the outside. In order to use the actually created segment in a measure (for example, to deliver e-mail magazines to targeted persons), it is necessary to output a list of groups corresponding to that segment (for example, a list of users aged under 50 with a unit purchase price of 250 Yen or more) to the outside. When the user operates the segment output button 58 e, the control unit 10 detects that the segment output button 58 e has been operated, and generates a user interface for output 59 shown in FIG. 33 and displays the same on the monitor 3. In the user interface for output 59, it is possible to select a feature value output together with the segment to be output. Then, the control unit 10 outputs corresponding data as a file such as CSV based on the extracted segment. As a result, the corresponding data can be downloaded to an external device and the like and be used.

The simulation button 58 f is a button operated in obtaining how a value of an objective variable changes when a value of a feature value is changed with respect to the selected segment based on the learned prediction model. When the user operates the simulation button 58 f, the control unit 10 detects that the simulation button 58 f has been operated and executes a simulation which will be described below.

Simulation Function

The data analyzing device 1 has a simulation function. The simulation function is a function which can be executed as needed, and is a function which can obtain, after a segment is selected as described above, how the value of the objective variable changes when the value of the feature value of the selected segment is changed based on the learned prediction model. By executing the simulation function, for example, it is possible to estimate an improvement effect when a measure is implemented. In this embodiment, it is possible to execute a simulation taking all analysis target data used for learning as a target and a simulation taking a specific group (segment) as a target; however, the number of user interfaces is one. The user interface may also be set different between the simulation taking all analysis target data used for learning as a target and the simulation taking a specific group as a target.

When the control unit 10 detects that the simulation button 58 f has been operated, the control unit 10 generates a user interface for simulation 61 as shown in FIG. 34 and displays the same on the monitor 3. The user interface for simulation 61 is provided with a feature value display region 61 a which displays a selected feature value, a slide bar 61 b, a contribution degree display region 61 c, and a graph display region 61 d. Although a specified number of feature values are displayed in the feature value display region 61 a, this number can be increased. For the feature values displayed in the feature value display region 61 a, the data analyzing device 1 automatically selects from feature values which are specified as control variables in a case where the user has specified in advance as “control variables”, feature values used for selection conditions of the selected segments, feature values having a high-ranking importance, feature values having a large contribution to the objective variable of the selected group, etc. As a result, the relation between a representative value of a plurality of feature values used in the prediction model and the numeric value of the objective variable is displayed on the monitor 3. That is, as described above, when automatically generating feature values, a large amount of feature values are automatically generated. As a result, when these feature values are all displayed on the user interface, many feature values that do not contribute to the objective variable are also included and it is difficult for the user to obtain a desired result. Therefore, the data analyzing device 1 automatically selects feature values that are likely to be effective and presents the same to the user, thereby enabling a quick and effective simulation. It is possible to display on the monitor 3 only feature values having a contribution degree equal to or greater than a predetermined value to the objective variable. In addition, the user may select the feature values to be displayed in the feature value display region 61 a.

The control variable is a feature value that can be controlled by the user, and since the feature value can be adjusted by the user, the simulation result can be actually executed as a measure. In other words, simulation is useful because it is possible to perform a simulation executable as a measure.

The aforementioned importance is calculated by an importance calculating unit 43 shown in FIG. 2. The importance of a feature value is known under the name Feature Importance; various calculation methods have been proposed, and any calculation method may be used. For example, in a linear multiple regression model represented by the following equation (1), coefficients a1, a2, . . . for each feature value x1, x2, . . . are obtained and the absolute value thereof may be used as the value of importance.

y=a1x1+a2x2+ . . . +anxn  (1)

Alternatively, instead of using the coefficients directly, normalization coefficients which have been corrected such that the magnitudes of the feature values x1, x2, . . . are equal may be used as the importance. After conducting such an analysis of importance, the control unit 10 extracts the ones having a high-ranking importance. The number to be filled into the “high rank” may be, for example, 2 or more, 5 or more, 10 or more, or 20 or more. The number to be filled into the “high rank” may be automatically set by the control unit 10, or may be set to any number by the user.

The contribution degree is calculated by the control unit 10. The contribution degree of a feature value can be obtained by an analysis method called linear multiple regression analysis. In the linear multiple regression analysis, a prediction equation (2) represented by the following format is used.

y=a1x1+a2x2+a3x3+ . . . +anxn+b  (2)

In the equation, y represents a prediction value, x1, x2, represent values (explanatory variables) of each feature value, and a1, a2, . . . represent coefficients for each feature value. In addition, b is a constant term. In the multiple regression analysis, the coefficient a and the constant term b are learned such that the value of y approaches the objective variable for each data.

According to the above equation (2), the prediction value y is composed of the sum of terms (a1x1, a2x2, . . . ) relating to each feature value and the constant term. It can be interpreted that the larger the absolute value of the term, the greater influence the feature value has on prediction.

Therefore, the product aixi of the coefficient and the value of the feature value is defined as the contribution degree of the feature value i. When the contribution degree is averaged for prediction of a plurality of data, for any data group, an average contribution degree to the prediction of that data group can be calculated.

For example, in the case of y=3x1−2x2+1, when taking an average of four data, feature x1 has a slightly positive contribution degree to the prediction value, and feature x2 has a large negative contribution degree to the prediction value.

Procedures of calculating the contribution degree by the linear multiple regression analysis of the above equation have been described in this example. However, the same calculation can be performed by approximating each prediction with a linear model even with a non-linear algorithm (for example, Scott M. Lundberg, “Consistent Individualized Feature Attribution for Tree Ensembles” (2018)).

The slide bar 61 b is generated by the adjusting unit 41 shown in FIG. 2 and displayed on the monitor 3. The adjusting unit 41 is a part that receives an adjustment of a representative value of a feature value based on a user's operation input, and the adjusting unit 41 is configured to, when representative values of a plurality of feature values are displayed on the monitor 3, receive the adjustment of a representative value for each feature value displayed on the monitor 3. Therefore, as shown in FIG. 34, the slide bar 61 b is provided for each feature value.

The slide bar 61 b is configured to be adjustable in two directions, a direction in which the representative value is increased and a direction in which the representative value is decreased, by sliding in a left and right direction. Either direction may be the increasing direction. Moreover, the operation direction of the slide bar 61 b is not limited to the left and right direction, and may also be a vertical direction. In addition, various operation means capable of increasing and decreasing the representative value can be provided other than the slide bar 61 b. For example, an input region where the representative value can be directly input may be provided.

A simulation unit 42 shown in FIG. 2 is a part which changes the feature values of a plurality of attributes according to adjustment amount of the representative value received by the adjusting unit 41, recalculates the numeric value of the objective variable from the prediction model and displays on the monitor 3. Specifically, when the representative value is changed by the operation of the slide bar 61 b, the simulation unit 42 obtains the changed representative value from the adjusting unit 41 and calculates the prediction value at the time of that value from the learned prediction model. The calculation result is displayed as a graph in the graph display region 61 d. Two types of calculations results, i.e., a calculation result before adjustment and a calculation result after adjustment, are displayed in the graph display region 61 d. In addition, a graph showing how much each feature value has contributed to the change in the objective variable is updated and displayed in the contribution degree display region 61 c.

The value of each displayed feature value represents an average value of a group being simulated. Therefore, in practice, lines smaller than this value and lines greater than this value are also included. When the representative value is adjusted by the slide bar 61 b, the values of all lines are offset so that the average value matches a specified value (see FIG. 35). In the example shown in FIG. 35, in a case where the adjustment amount is +0.1, calculation is performed by increasing all DM opening rates of users by +0.1 only. In other words, simulation is provided for a group rather than for one data, and thus a simulation method which changes the average value is used.

The adjusting unit 41 is configured to indicate a change tendency of the objective variable for each adjustment direction before adjusting the representative value. Specifically, a gradation is attached to the background color of the slide bar 61 b, and this color expresses the direction and degree of change of the objective variable. When the change of the color is small, the effect on the objective variable is small, and when the change of the color is large, the effect on the objective variable is large. In this way, it is possible to know which feature value should be operated before actually operating the slide bar 61 b. In addition, black color indicates a direction in which the effect is decreasing, and white color indicates a direction in which the effect is increasing. The display form of the slide bar 61 b is not limited to the aforementioned forms; the display form is only necessary to be a form indicating the change tendency of the objective variable for each adjustment direction, and a blue color (a direction in which the effect is increasing) and a red color (a direction in which the effect is decreasing), etc. may also be used.

The user interface for simulation 61 is provided with a comment display region 61 e for automatically generating a sentence explaining a summary of a result such as to what extent an objective variable has changed by changing which feature value, and displaying the sentence together with a graph. The sentence is generated by the control unit 10.

Effect of Embodiment(s)

As described above, according to the data analyzing device 1 according to the embodiment, it is possible to set at least one attribute that is a numeric type as an attribute of an aggregation target, set at least one attribute that is a category type as an attribute of an aggregation unit, and aggregate, for each category value of the attribute of the aggregation unit, a numeric value of the attribute of the aggregation target based on a previously prepared aggregation function to automatically generate and display a new objective variable candidate. Further, it is possible to receive a selection of an objective variable by a user from among the displayed objective variable candidates and to automatically generate a prediction model for predicting the selected objective variable, and thus even those who are unskilled in data processing can conduct an analysis freely.

Further, a predetermined function is applied to attributes excluding at least a part of attribute values of attributes of the aggregation target used when generating an objective variable, and thus a situation in which the information of the objective variable is unintentionally leaked to the feature value is avoided. Therefore, leaks can be automatically prevented even for those who are not skilled in machine learning.

Moreover, a feature value including the information of at least a part of attribute values of attributes of the aggregation target used for the objective variable is excluded to obtain the final feature value, and thus a situation in which the information of the objective variable is unintentionally leaked to the feature value is avoided. Therefore, leaks can be automatically prevented even for those who are not skilled in machine learning.

In addition, the objective variable candidate can be automatically generated by the objective variable candidate generating unit 14, and the objective variable candidate can be extracted based on the keyword information and the attribute and displayed on the monitor 3. This makes it easy for the user to select the objective variable candidate.

Further, it is possible to generate a prediction model based on a new feature value automatically generated by the feature value automatic generating unit 15 and a feature value of an original attribute included in the analysis target data, and it is possible to divide, for each of a plurality of feature values, by determining a division point indicating a change in influence on an objective variable, each feature value into a plurality of segments and calculate an evaluation value using an influence degree of each segment on the objective variable as an index. Then, since the segments of the feature values for which the evaluation values have been calculated are displayed on the monitor 3, it is possible to present to the user which feature value influences and how it influences the objective variable and on this basis, the user can easily conduct an in-depth analysis.

In addition, it is possible to receive an adjustment of a representative value based on a user's operation input, change the feature values of a plurality of attributes according to adjustment amount of the representative value, recalculate the numeric value of the objective variable from the prediction model, and display the calculation result on the display unit. Therefore, it is possible to determine in advance the propriety of a measure by simulating the change of the objective variable due to the change of the value of the feature values.

The embodiments described above are merely illustrative in all respects and should not be interpreted limitedly. Furthermore, all variations and modifications that fall within equivalent scopes of the claims fall within the scope of the invention.

As described above, the data analyzing device according to the invention can be used in cases of attempting to obtain useful knowledge that has been unknown from among a large amount of information. 

What is claimed is:
 1. A data analyzing device for analyzing analysis target data, comprising: a data input unit which receives an input of analysis target data including a plurality of attributes, a feature value automatic generating unit which automatically generates a new feature value by applying a predetermined function to a single attribute or a combination of a plurality of attributes, an analyzing unit which generates a prediction model for predicting an objective variable based on feature values of a plurality of attributes including a feature value of an original attribute included in the analysis target data and a new feature value generated by the feature value automatic generating unit, an evaluating unit which, for each of the plurality of feature values, by determining a division point indicating a change in influence on an objective variable, divides each feature value into a plurality of segments and calculates an evaluation value using an influence degree of each segment on the objective variable as an index, and a display unit which displays the segments of the feature values for which the evaluation values have been calculated by the evaluating unit.
 2. The data analyzing device according to claim 1, wherein the display unit is configured to selectively display the segments of the feature values for which the evaluation values have been calculated by the evaluating unit.
 3. The data analyzing device according to claim 1, wherein the display unit is configured to preferentially display the segments of the feature values for which the evaluation values have been calculated by the evaluating unit.
 4. The data analyzing device according to claim 1, wherein the display unit is configured to display a segment of a feature value having a high-ranking evaluation value calculated by the evaluating unit.
 5. The data analyzing device according to claim 1, wherein the evaluating unit is configured to determine the division point where the evaluation value is optimal.
 6. The data analyzing device according to claim 1, wherein the evaluating unit is configured to, by determining a division point indicating a change in influence on an objective variable under a compound condition combining a plurality of feature values, divide each feature value into a plurality of segments and calculate an evaluation value using an influence degree of each segment on the objective variable as an index, and the display unit is configured to display the segments of the feature values for which the evaluation values under the compound condition have been calculated.
 7. The data analyzing device according to claim 1, wherein the evaluating unit is configured to calculate a share of data included in the segments, and the display unit is configured to display the share calculated by the evaluating unit.
 8. The data analyzing device according to claim 1, wherein the evaluating unit is configured to calculate an average value of objective variables, and the display unit is configured to display the average value of the objective variables.
 9. The data analyzing device according to claim 1, wherein the display unit is configured to be capable of displaying switching between a first display form in which a segment having one feature value is displayed and a second display form in which a segment having a plurality of feature values is displayed.
 10. The data analyzing device according to claim 1, wherein the display unit is configured to display a relation between a representative value of a plurality of feature values used in the prediction model and a numeric value of an objective variable, and the data analyzing device further comprises: an adjusting unit which receives an adjustment of the representative value based on a user's operation input, and a simulation unit which changes the feature values of a plurality of attributes according to adjustment amount of the representative value, recalculates the numeric value of the objective variable from the prediction model and displays on the display unit. 